RU2689964C2 - Construction element for creating tunnel, tunnel comprising such element, and methods of constructing such element and such tunnel - Google Patents

Abstract

FIELD: construction.SUBSTANCE: group of inventions relates to a building element for creating a tunnel, as well as a method of producing a building element for creating tunnels, particularly underground tunnels. Construction element for tunnel creation comprises first incompressible layer of concrete and second compressing layer attached to first layer to form single-piece prefabricated building element to be built in tunnel section. At the same time the second layer contains multiple devices, each of which has a solid body enclosing empty space, at the same time the solid body of devices is equipped with coating from adhesive film for reliable fastening of devices with the first layer. Proposed method comprises the following stages: obtaining first incompressible concrete layer and obtaining second contracting layer reliably attached to first layer. At that, the second layer is obtained from multiple devices, each of which has a solid housing enclosing an empty space. At that, during production of the second layer the method includes the following stages: creation of coating of solid housing of devices with adhesive film and laying of devices equipped with coating on the first layer.EFFECT: technical result consists in improvement of adhesion of devices to the first layer and improved damping of soil subsidence, acting on the tunnel.13 cl, 20 dwg

Description

BACKGROUND INVENTIONS

The invention relates to the creation of tunnels, in particular, underground tunnels, and to the building blocks of such tunnels.

PRIOR ART

In the area of tunnels, in general, a recess is cut off underground, and then a tunnel is constructed in this recess using tunnel lining blocks (hereinafter tubing). Tubes correspond to the elements that make up the annular section of the tunnel when assembled together. When the excavation breaks off in the ground, the equilibrium state of the soil is disturbed and the latter creates a more or less intense pressure, which tends to close the excavation formed in this way, this phenomenon is called "subsidence".

French patent application FR1200989 can be contrasted, which discloses a ground subsidence damping system containing a coating covering the outer surface of the tunnel wall and which contains devices, each of which is provided with a through hole. These devices with a through hole create free space in the coating, considered as residual volume, which is involved, in particular, in damping the subsidence of the soil. In particular, the soil pressure usually takes up residual volume, i.e. volume left unoccupied devices that provides pressure damping. But to create a coating, devices must be introduced into the space contoured by the outer surface of the tunnel wall and the inner surface of the soil wall. However, when the construction of the tunnel is completed, the soil elements can stick together in the contoured space and prevent the introduction of devices, which can prevent the devices from being evenly laid on the outer surface of the tunnel wall.

You can also oppose the British patent application GB 2013757, which reveals a way to create a tunnel of precast concrete tubing. Prior to use in the construction of the tunnel, each precast concrete tubing contains a layer of compressible material, such as polyethylene foam, glued onto the outer surface of the tubing. But the foam is unstable and can decompose with time, as a result losing the properties of mechanical compression and deformation. In addition, this synthetic foam can pollute the environment.

Therefore, it is preferable to create a building element suitable for the construction of tunnels, and tunnels constructed from such elements and, in particular, to create ways to construct such an element and to build such a tunnel.

OBJECTIVE OF THE INVENTION

One object of the invention is to eliminate the drawbacks outlined above and, in particular, to create a device that is easy to obtain and implement, for damping the subsidence of the soil acting on the tunnel.

According to one aspect, a construction element for creating a tunnel is proposed, comprising a first incompressible layer of concrete and a second compressible layer securely bonded to the first layer to form a monobloc prefabricated building element configured to be embedded in the tunnel section.

The second layer contains a multitude of devices, each having a solid body enclosing empty space.

Thus, a prefabricated building element is provided that is suitable for creating a tunnel section. Such a monoblock building element is easily tilted and its manufacture can be monitored to obtain a uniform section of the tunnel to control the behavior of the tunnel when the ground subsides. In addition, the empty spaces of the devices determine the compressibility of the second layer. In other words, empty spaces provide soil subsidence and removal of transmitted stresses on the first layer.

The second layer may comprise devices, each provided with a through hole.

The second layer may also contain devices for which a solid body determines the configuration of at least one closed cavity.

The hard case of devices can be made of ceramics.

A solid device case can be provided with a coating of adhesive film to secure the device with the first layer.

Adhesive foam can be prepared from mortar.

The building element may further comprise a third protective layer located on the second layer. At the same time, the second layer is protected in order to preserve its integrity, for example, during transportation of the building element before the latter is installed in the tunnel section.

According to another aspect, a tunnel located inside a recess dug in the ground, at least one section of the tunnel is created from at least one two-layer building element, as defined in the above description.

Each two-layer building element may contain a third protective layer located on the second layer, and the tunnel may contain filling material occupying free space contoured between the third protective layer and the ground.

According to another aspect, a method for producing a building element for creating a tunnel is proposed, comprising the following steps:

- obtaining the first incompressible layer of concrete; and

- getting the second compressible layer, securely fastened with the first layer, to form a monoblock precast building element, made with the possibility of embedding in the section of the tunnel.

In this method, the second layer is obtained from a variety of devices, each having a solid body enclosing an empty space.

The second layer may comprise devices, each provided with a through-hole and / or devices for which a solid body defines the configuration of at least one closed cavity.

Obtaining a second layer may contain the following steps:

- execution of the coating of the solid case of the device with an adhesive film; and

- laying coated devices on the first layer.

The method may also comprise the step of creating a protection in which the third protective layer is laid on the second layer.

According to another aspect, a method for constructing a tunnel is proposed, comprising the following steps:

- the creation of excavations in the ground using a tunneling machine;

- the creation of sections of the tunnel, located inside the recess, at least one section created from at least one two-layer building element, as defined in the above description, with the progressive advance of the tunnel penetration machine.

Each two-layer building element may contain a third protective layer located on the second layer, and the free space contoured between the third protective layer and the ground may be filled with a filling material.

BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages and features should be better understood from the following description of specific embodiments and implementations of the invention, given only the quality of non-limiting examples and presented in the accompanying drawings, which show the following.

FIG. 1 is a schematic sectional view of an embodiment of a tunnel according to the invention.

FIG. 2 schematically shows an embodiment of the construction element according to the invention.

FIG. 3 is a schematic representation of the equilibrium state after the subsidence of the soil.

FIG. 4 is a schematic isometric view of an embodiment of a device equipped with a through hole.

FIG. 5 is a schematic sectional view of the device of FIG. four.

FIG. 6 is a schematic top view of another embodiment of a device equipped with a through hole.

FIG. 7 is a schematic sectional view taken along line A-A of FIG. 6

FIG. 8 schematically shows another embodiment of the construction element.

FIG. 9 is a schematic isometric view of an embodiment of a device equipped with a closed cavity.

FIG. 10 schematically illustrates a sectional view of the device shown in FIG. 9.

FIG. 11 schematically illustrates a left-side view of the device shown in FIG. 9.

FIG. 12-18 schematically illustrate the main stages of the implementation of the method for creating a building element.

FIG. 19 schematically illustrates a cross section of a tunnel penetrating machine creating a tunnel of FIG. one.

FIG. 20 schematically illustrates a sectional view of a fragment of FIG. nineteen.

DETAILED DESCRIPTION

In general, although the present invention has specific advantages in the field of tunnels, it is also applicable to any system that is created in an underground excavation and which is designed to withstand soil subsidence, for example, partially or completely burrowed support shoes or tanks.

FIG. 1 presents a tunnel 1 created in a recess 2 dug in the ground 3, in other words, an underground tunnel. Tunnel 1 may be open and in the shape of an inverted U and may also be closed and may be oval or any other shape. Preferably, tunnel 1 has a generally tubular shape. The tunnel 1 contains sections 4, located in the recess 2. At least one section 4 and, preferably, each section 4, is made up of building elements 5 assembled together. At least one building element 5 comprises a first incompressible layer 6 of concrete. For example, when sections 4 of tunnel 1 have an annular shape, the first layer 6 has the shape of a curved hexahedron. The building element 5 further comprises a second compressible layer 7 securely bonded to the first layer 6 to form a precast building element 5 of a monoblock type. Building element 5 is prefabricated, i.e. pre-fabricated, prior to the creation of tunnel 1. In other words, building element 5 is created in advance, and several building elements 5 are then assembled together to create section 4 of tunnel 1. The need for a damping coating by injecting material between the tubing and the ground 3 is eliminated. The building element 5 actually has a collapsible layer 7 previously included in the composition, and thus has a built-in mechanical damping property. In addition, a monoblock element means a transportable element that retains its physical integrity and its mechanical properties during transportation, for example, when an element moves from its manufacturing site to the site of section 4 of the tunnel 1 where it is installed. In other words, the building element 5 is configured to be embedded in section 4 of tunnel 1, and in particular in the created section 4.

In general, the second layer 7 comprises several devices 8, as illustrated in FIG. 2 and 8, each having a solid body 9, having in the composition an empty space 10. An empty space is a closed or open cavity located in the body, the configuration of which is determined by the device body. The second layer 7 is compressible, i.e. may be deformed when the ground subsides 3. In particular, devices 8 have a deformable solid body 9. This means that the devices can be deformed when they are broken or curved, in particular, taking into account their empty space 10, to ensure the deformation of the second layer 7. The second layer 7 additionally contains gaps 7a, i.e. empty spaces located between devices 8. Thus, a compressible layer 7 having a residual volume is provided, composed by adding empty spaces of each of devices 8 and spaces 7a, which provide the damping property of subsidence of soil 3. Indeed, in the initial state, soil 3 transmits the initial deposition pressure on the tunnel 1. Taking into account the movements of the soil 3, the latter should tend to settle towards the central part of the excavation 2. The deformation of the devices 8 should therefore provide 3, the translational movement in a direction toward the central part of the tunnel 1, while the ground 3, enters into an equilibrium state. In equilibrium, the settling pressure is less than the initial pressure. The second compressible layer 7 therefore provides damping of the subsidence of the soil until an equilibrium state is reached, in which the settling pressure is carried by the building element 5, i.e. the first incompressible layer 6 does not break under the pressure of sedimentation in the equilibrium state.

For example, devices 8 may be made of ceramic. Ceramics provides good resistance, while being fragile for effective damping of ground subsidence 3. When the bodies 9 of the device 8 break, the soil 3 can sink towards the central part of the tunnel 1. The devices 8 can also be made of glass, cement, or mortar which, like ceramics, are materials that can break under the action of soil subsidence 3. Alternatively, devices 8 can be made of metal or of deformable plastic. When the devices 8 have a deformable housing, they also provide damping for subsidence.

FIG. 2 shows a preferred embodiment in which each of the devices 8 of the second compressible layer 7 comprises a housing 9 provided with a through hole 10 (illustrated in FIG. 4-7 and described below). The building element 5 embedded in the tunnel sections is also shown in FIG. 2. Prefabricated building element 5 is monoblock and contains the first concrete layer 6 and the second compressible layer 7 formed by the devices 8. When the first layer 6 has the shape of a curvilinear hexahedron, the construction element 5 forms a tubing with a compressible part 7 configured to form an annular section tunnel 1. The thickness E of the second layer 7 is selected according to the damping of subsidence of the soil 3, which is required to be obtained. In particular, the thickness E is selected according to the movement of the soil 3 with respect to its initial position, which can be supported by the building element 5. In the initial position, the soil 3 is located at the initial distance Gi from the outer surface of the first layer 6. The initial distance Gi corresponds to the sum of the initial thickness E of the second layer 7, the thickness of the third protective layer 12 and the thickness of the free space F. In addition, the thickness E also depends on the compressibility of the devices 8. The devices 8 are additionally covered with an adhesive film 11 for reliable bonding them with the first layer 6. In particular, the adhesive layer 11 provides the means 8 with a secure bond with each other and with the first concrete layer 6. In this method, building element 5 is monoblock and transportable for embedding in the tunnel section when the latter forms . The adhesive film 11 preferably contains a mortar that effectively adheres to the concrete first layer 6. The mortar contains cement, sand and water. The mortar is hardening and hardening to bond the devices 8 to each other and to ensure that the devices stick to the first layer 6. In particular, the adhesive film 11 covers the outer surface of the device 8, without creating an obstacle in the through hole 10. Other adhesive elements can be used Coating devices 8, for example epoxy based adhesive, etc.

Preferably, the building element 5 may comprise a third protective layer 12 located on the second layer 7. More specifically, the third protective layer 12 is a thin layer compared to the first and second layers 6, 7. In the general method, the third protective layer 12 is bonded to the second layer 7 for mechanical bonding with the second layer 7. The third protective layer 12 protects the second layer 7 from impacts, for example, when the building element 5 is turned, to prevent fractures of the bodies 9 of the devices 8, in particular those located on the periphery of the building ementa 5. In general terms, when creating a tunnel section, the free space F is created between the inner surface of the cavity and the outer surface of the tunnel section, i.e., the outer surface of the building element 5. When the building element 5 does not contain a third protective layer, the outer surface of the section corresponds to the outer surface of the second layer 7, as shown in FIG. 8. When the building element 5 comprises a third protective layer 12, the outer surface is the surface of the third protective layer 12, as illustrated in FIG. 2. At the same time, in order to prevent soil collapse 3 into free space F and destruction of the section, the filling material 23, such as mortar or gravel, is injected to fill this free space F. In the variant where the second layer 7 contains devices 8 through hole 10, the third protective layer 12, which in addition is impermeable to the filling material 23 used to fill the free space F, is laid on the second layer 7. In this case, the third protective layer 12, in particular, to prevent It protects the filling of the through holes 10 on the first layers of the devices 8 with the filling material 23. The third protective layer 12 prevents the mortar or gravel from penetrating into the through holes 10, which can reduce the damping properties of the building elements 5. The third protective layer 12 provides the insulation to the second compressive layer 7 material 23. The third protective layer 12, thus, ensures the preservation until the deformation of the second layer 7 of residual volume, which ensures damping of the subsidence of the soil 3. The third the protective layer 12 may be made of plastic or mortar.

When the soil 3 settles, as illustrated in FIG. 3, the second compressible layer 7 is deformed and moves the soil 3 towards the center of the tunnel. Soil 3 can break or deform the device 8 until an equilibrium state is reached, in which soil 3 is at an equilibrium distance Ge from the outer surface of the first layer 6. The equilibrium distance Ge is less than the initial distance Gi. The fracture resistance of the devices 8 is less than the soil sinking pressure, which ensures the destruction of the devices 8. The broken devices are represented by the reference position 8a. In other words, all or some of the devices 8 may be in the state in which they are broken. This provides a cushioning movement of soil 3 without damage to the tunnel.

FIG. 4-7 illustrate two embodiments of the device 8, provided with a through hole 10, with the possibility of being used in the second compressive layer 7 of the building element 5. In FIG. 4 and 5, the device 8 has the form of a pipe containing a through hole 10, corresponding to a channel passing along the longitudinal axis A1 of the pipe. The device 8 may also contain several through holes, and preferably each device 8 contains one through hole to simplify its manufacture. Preferably, each device 8 in the form of a pipe has a height H, an outer diameter d ₁ and an inner diameter d ₂ . Preferably, the height H is equal to the outer diameter d ₁ , in particular, to obtain a second layer 7 having an essentially constant thickness E. These dimensions ensure that the tubular device 8 carries the calculated load until fracture. The device 8 is also covered with an adhesive film 11a, which surrounds the outer surface of the device 8. Depending on the method of applying the coating, the adhesive film 11b can be placed on the inner surface of the wall of the through hole 10 without creating an obstacle in it. The devices 8 can, for example, be placed in a mortar and a sieve can be used to remove excess mortar. In this case, as illustrated in FIG. 4 and 5, the mortar film 11a covers the outer surface of the devices, and another mortar film 11b adheres to the inner surface of the wall of the through hole 10 without creating an obstacle in it. According to another embodiment, the through hole 10 of the devices 8 is insulated, and the outer surface of the devices 8 has a coating of adhesive layer 11. In this case, as illustrated in FIG. 2, the inner surface of the wall does not have a coating of the adhesive layer, which guarantees obtaining increased empty space in the media.

FIG. 6 and 7 show another embodiment of a device 8 with a through hole 10 having the form of a ring. The ring may be toroidal and may have an annular cross-section, as illustrated in FIG. 6. The ring may have a diameter d _{s of the} torus and an internal diameter d _i . In this embodiment, the adhesive film 11 surrounds the outer surface of the housing 9 of the device 8, penetrating partially into the through hole 10, without creating an obstacle in it.

Preferably, the devices (pipes or rings) located inside the second layer 7 are all essentially identical to obtain a uniform second layer 7. In other words, they cannot be inserted into each other. The second layer 7 preferably comprises a device 8 having a generally tubular shape, since they are simpler to manufacture than devices 8 in a generally annular form.

FIG. 8 shows another embodiment of the second compressible layer 7. In this other embodiment, each of the devices 8 comprises a solid body 9 defining the configuration of at least one closed cavity (illustrated additionally in FIGS. 9-11). The building element 5 is monoblock and contains the first concrete layer 6 and the second compressible layer 7 formed by the devices 8. In this embodiment, there is no need for the third protective layer 12 for the building element 5. Indeed, the housing 9 of the devices 8 defining the configuration of one or more closed cavities , prevents entry of mortar or gravel injected into free space F in these cavities. The building element 5 may, however, contain devices having a body defining the configuration of one or more closed cavities, and a third protective layer 12 to protect the second layer 7 when moving element 5, in particular to prevent destruction of the devices 8 during transportation. In this case, the third protective layer 12 ensures impermeability to the second layer 7, preventing the material 23 from filling the gaps 7a.

FIG. 9-11 illustrate an embodiment of the device 8, the body 9 of which defines the configuration of at least one closed cavity 10. Preferably, the device 8 has a solid body 9 made of ceramic. Ceramics is suitable for the manufacture of these devices 8, because it is plastic before firing and provides the possibility of closing the cavity 10 in the device 8 and becomes solid after firing. Closed cavity 10 means the empty space enclosed in the device 8. The solid body 9 of the device 8 is, in particular, impermeable to liquid, for example hermetically sealed to prevent penetration of mortar into the liquid phase before solidification. For example, the housing 9 of the device 8 passes along the longitudinal axis A of the device 8 and contains two closed ends 13, 14. Each of the closed ends 13, 14 may have a linear shape. In the first embodiment, as illustrated in FIG. 9 and 10, the ends 13, 14 are parallel to each other. Alternatively, the ends 13, 14 may be perpendicular to each other. For example, the housing 9 of the device 8 has a cylindrical shape. Here cylinder means a solid body bounded by a cylindrical surface created by a straight line, called a generator, moving along a closed flat curve, a known axial line and two parallel planes that intersect the generators. In particular, the housing 9 may be in the form of a pipe. The device 8 may also contain several cavities communicating with or not communicating with each other. Preferably, the closed cavities 10 of the devices 8 prevent their insertion into each other, regardless of their size and shape.

Alternatively, the building element 5 contains a second compressible layer 7 which can contain both, devices 8, each provided with a through hole 10, and devices 8 with a solid body 9, which defines the configuration of at least one closed cavity 10.

FIG. 12-18, the main steps of an embodiment of a method for manufacturing a building element 5 defined above herein are presented. In general, the building element 5 is made by performing the following steps:

- obtaining the first incompressible layer 6 of concrete; and

- obtaining a second compressible layer 7, securely fastened to the first layer 6, from a variety of devices 8, each of which has a solid body 9 having an empty space 10, to form a monoblock prefabricated building element 5 configured to be embedded in a tunnel section 4 one.

The solid bodies 9 of the devices 8 are each provided with a through-hole and / or the body of the devices comprises at least one closed cavity.

For example, for the manufacture of the first layer 6 of concrete, formwork 30 is open and curvilinear, rectangular in plan, to create a tubing shape, as illustrated in FIG. 12. As an option, the formwork is open and not curved to create sections of the tunnel of various shapes, for example, in the shape of a letter U or oval. Liquid concrete 31 is then poured into the formwork 30, as illustrated in FIG. 13. Metal rods can also be added to liquid concrete 31 to produce incompressible reinforced concrete of the first layer. Then the first formwork shield 32 is applied, which is placed on the surface of the concrete 31 and which moves along the surface to form a curvilinear outer surface. Concrete 31 is allowed to harden, or completely and in this case the concrete gets full hardness, or partially and in this case the concrete does not completely harden, but hardens sufficiently on the surface to maintain the curvature given by the first shield 32 of the formwork. The first formwork shield 32 is then removed and, thus, a first layer 6 is obtained having a base and an outer surface that are curvilinear, as illustrated in FIG. 14. The solid bodies 9 of the devices 8 receive in advance a coating with an adhesive film 11. The elements of the formwork 33 are additionally fixed at the edges of the formwork 30 in order to lift the formwork 30 and enable the second layer 7 to be made, as illustrated in FIG. 15. The coated devices 34 are then laid down in the formwork 30 and, more specifically, on the outer surface of the first layer 6. According to one embodiment, when the coated devices 34 are laid down, the concrete of the first layer is not yet completely cured. In this embodiment, an adhesive layer 11 of mortar is applied, which must adhere to the outer surface of the first layer 6, which is not completely cured. Alternatively, you can wait for the concrete to fully cure before laying down the devices 8. According to this option, an adhesive layer 11 of glue, such as an epoxy resin adhesive, which adheres to the hard concrete surface, should be applied. In addition, when the adhesive film 11 contains mortar, the devices 34 coated with mortar are placed on the first layer 6 until the mortar solidifies. The building solution is then allowed to harden to securely bond the second compressible layer 7 with the first layer 6. A second formwork shield 35 is then applied, which is installed and moved on the surface of the coated devices 34 to form a curvilinear outer surface on the second layer 7, as illustrated in FIG. 15. Then, the adhesive layer 11 is allowed to adhere so that the devices bind to each other, and to securely secure the second layer 7 to the first layer 6. The second shield 35 of the formwork is then removed and a precast monoblock element 5 is formed, surrounded by the formwork 30, illustrated in FIG. 16. Alternatively, as illustrated in FIG. 17, the third protective layer can be made by laying mortar 36 on the second layer 7 and moving the third shield of the formwork 37 to bend the outer surface of the third layer. The formwork 30 and the formwork elements 33, as well as the third formwork shield 37, if used, are then removed to obtain a one-piece prefabricated building element 5, as illustrated in FIG. 18.

An embodiment for creating a tunnel 1 described above and shown in FIG. 1 is shown in FIG. 19 and 20. According to this embodiment, the tunneling machine 15 excavates recess 2 in soil 3 in direction F1. The head of the tunneling machine 20 is equipped with a means 21 for the destruction of the rock of the soil 3 and contains a device for extracting the rock, not presented for the sake of simplicity. Part of the tunnel boring machine 15 performs the installation of building elements 5 as the tunnel boring machine 15 moves progressively in the direction F1. The tunnel boring machine 15 further comprises an injection device 22 for injecting a filling material 23, for example, mortar or gravel, to fill the free space F contoured between the building elements 5 and the inner wall surface of the recess 2 formed by advancing the tunnel boring machine 15. Arrow F2 illustrates the path chosen by the filler material 23 when the latter is injected. The injection of the filling material 23 provides for the creation of a filling layer occupying the free space F between the structural elements 5 and the ground 3.

In general, the way to create a tunnel contains the following steps:

- the creation of excavation 2 in the ground 3 using a tunnel boring machine 15;

- the creation of sections 4 of the tunnel 1, located inside the recess 2, at least one section 4 is created from at least one building element 5, as defined in the above description, as the forward tunneling machine 15 moves forward.

More specifically, when creating section 4 of the tunnel 1, a free space F is kept, contoured between the outer surface of the wall of the tunnel 1 and the inner surface of the wall of the recess 2 for installing construction elements to form section 4 of the tunnel 1. Free space F is then filled with filling material 23.

The construction element described above facilitates the construction of the tunnel and at the same time ensures damping of the subsidence in which the tunnel is located. In addition, it provides an improved way to create a tunnel. Such a building element provides a reduction in the thickness of conventional tubing, which significantly reduces the consumption of concrete to create a tunnel.

Claims (20)

1. Building element to create a tunnel containing the first incompressible layer (6) of concrete and the second compressible layer (7), securely fastened to the first layer (6), to form a monoblock prefabricated building element, configured to be embedded in the tunnel section, characterized by that the second layer (7) contains a plurality of devices (8), each of which has a solid body (9) containing an empty space (10), while the solid body (9) of the devices (8) is provided with a coating of adhesive film ( 11) to secure the device Stations (8) with the first layer (6). 2. A construction element according to claim 1, in which the devices (8) are provided with a through hole (10) each. 3. The building element of claim 1, wherein the devices (8) have a solid body (9) defining the configuration of at least one closed cavity (10). 4. Construction element in one of the paragraphs. 1, 2, in which the solid body (9) of the devices (8) is made of ceramic. 5. A construction element in one of claims 1, 4, in which the adhesive film (11) contains mortar. 6. Construction element in one of the paragraphs. 1 or 2, containing the third protective layer (12) located on the second layer (7). 7. The tunnel, located inside the excavation (2), dug in the ground (3), at least one section of the tunnel is created from at least one two-layer building element (6, 7) according to claim 1. 8. The tunnel according to claim 7, in which each two-layer building element (6, 7) contains a third protective layer (12) located on the second layer (7), and the filling material occupies free space contoured between the third protective layer (12) and ground (3). 9. The method of obtaining a building element to create a tunnel, containing the following steps: - obtaining the first incompressible layer (6) of concrete; and - getting the second compressible layer (7), securely fastened with the first layer (6), to form a monoblock prefabricated building element, made with the possibility of inclusion in the section of the tunnel, while the second layer (7) is obtained from a variety of devices, each of which has a solid body enclosing an empty space, while obtaining the second layer (7) contains the following steps: - creation of a coating of a solid case of devices with an adhesive film (11); and - laying of coated devices on the first layer (6). 10. A method according to claim 9, in which the device case (8) has a through hole (10). 11. A method according to claim 9 or 10, in which the devices (8) have a solid body (9) defining the configuration of at least one closed cavity (10). 12. The method according to one of paragraphs. 9 or 10, containing the step of creating protection, in which the third protective layer (12) is placed on the second layer (7). 13. A tunnel construction method comprising the following steps: - the creation of excavations in the ground using a tunneling machine; - the creation of sections of the tunnel, located inside the notches, at least one section created from at least one two-layer building element (6, 7) according to one of claims. 1 or 2 while advancing the tunnel boring machine.

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